1. SECOND CYCLE - MASTER'S DEGREE
  2. THE GRADUATE SCHOOL OF NATURAL AND APPLIED SCIENCES
  3. MECHANICAL ENGINEERING DEPARTMENT
  4. 1111 Mechanical Engineering
Course Information Course Learning Outcomes Course's Contribution To Program ECTS Workload Course Details
Print

COURSE INFORMATION
Course CodeCourse TitleL+P HourSemesterECTS
MAK 503THEORY OF ELASTICITY3 + 02nd Semester7,5

COURSE DESCRIPTION
Course Level Master's Degree
Course Type Elective
Course Objective Elastic Solids Mechanics stress, strain and constitutive equations to teach the basic concepts. Solution methods based on these concepts to explain the equations of motion and balance. Examine a variety of engineering problems, depending on boundary conditions.
Course Content Mathematical Foundations. Analysis of Stress. Analysis of Strain. Conservation laws. Linear Elasticity. Constitutive Equations. Generalized Hooke's Law. Fundamental Equations of Theory of Elasticity. Stress Problem. Displacement Problem. Compatibility Conditions. General Theory of Plane Elasticity. Plane Stress (Thin Plate Problem). Plane Strain (Long Cylinder Problem). Solutions in Cartesian Coordinates. Stress Functions. Airy Stress Function. Boundary Conditions. Polynomial Solutions. Biharmonik Functions. Examples. Fourier Series Solutions. Examples. Solutions in Polar Coordinates. Examples. Three Dimensional Elasticity. Saint-Venant Torsion and Bending Theory. Galerkin Vector. Papkovich-Neuber Solutions.
Prerequisites No the prerequisite of lesson.
Corequisite No the corequisite of lesson.
Mode of Delivery Face to Face

COURSE LEARNING OUTCOMES
1-Ability to have a broad education in the field of engineering -Ability to use engineering techniques and modern engineering tools -Mathematics, Science, and the ability to apply engineering knowledge in the field of Mechanical Engineering

COURSE'S CONTRIBUTION TO PROGRAM
PO 01PO 02PO 03PO 04PO 05PO 06PO 07PO 08PO 09PO 10PO 11PO 12PO 13PO 14
LO 00155444332521424
Sub Total55444332521424
Contribution55444332521424

ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
ActivitiesQuantityDuration (Hour)Total Work Load (Hour)
Course Duration (14 weeks/theoric+practical)14342
Hours for off-the-classroom study (Pre-study, practice)14570
Assignments10550
Final examination13333
Total Work Load

ECTS Credit of the Course





195

7,5
COURSE DETAILS
 Select Year   


 Course TermNoInstructors
Details 2022-2023 Spring1ÖZKAN ÖZBEK
Details 2015-2016 Spring1GÜRKAN ALTAN
Details 2015-2016 Fall1GÜRKAN ALTAN
Details 2014-2015 Spring1GÜRKAN ALTAN
Details 2014-2015 Fall1GÜRKAN ALTAN
Details 2013-2014 Spring1GÜRKAN ALTAN
Details 2013-2014 Fall1EMİN ERGUN
Details 2012-2013 Spring1HASAN ÇALLIOĞLU
Details 2012-2013 Fall1EMİN ERGUN
Details 2011-2012 Fall1EMİN ERGUN
Details 2010-2011 Fall1GÜRKAN ALTAN
Details 2009-2010 Spring1HASAN ÇALLIOĞLU
Details 2009-2010 Fall1HASAN ÇALLIOĞLU


Print

Course Details
Course Code Course Title L+P Hour Course Code Language Of Instruction Course Semester
MAK 503 THEORY OF ELASTICITY 3 + 0 1 Turkish 2022-2023 Spring
Course Coordinator  E-Mail  Phone Number  Course Location Attendance
Assoc. Prof. Dr. ÖZKAN ÖZBEK ozbek@pau.edu.tr MUH A0297 %
Goals Elastic Solids Mechanics stress, strain and constitutive equations to teach the basic concepts. Solution methods based on these concepts to explain the equations of motion and balance. Examine a variety of engineering problems, depending on boundary conditions.
Content Mathematical Foundations. Analysis of Stress. Analysis of Strain. Conservation laws. Linear Elasticity. Constitutive Equations. Generalized Hooke's Law. Fundamental Equations of Theory of Elasticity. Stress Problem. Displacement Problem. Compatibility Conditions. General Theory of Plane Elasticity. Plane Stress (Thin Plate Problem). Plane Strain (Long Cylinder Problem). Solutions in Cartesian Coordinates. Stress Functions. Airy Stress Function. Boundary Conditions. Polynomial Solutions. Biharmonik Functions. Examples. Fourier Series Solutions. Examples. Solutions in Polar Coordinates. Examples. Three Dimensional Elasticity. Saint-Venant Torsion and Bending Theory. Galerkin Vector. Papkovich-Neuber Solutions.
Topics
WeeksTopics
1 Introduction
2 Plane stress and plane strain
3 Two-dimensional problems in rectangular coordinates
4 Two-dimensional problems in rectangular coordinates
5 Two-dimensional problems in polar coordinates
6 Two-dimensional problems in polar coordinates
7 Two-dimensional problems in polar coordinates
8 Mid-Term Examination
9 Elementary problems of elasticity in three dimensions
10 Torsion
11 Torsion
12 Bending of Bars
13 Bending of Bars
14 Engineering applications
Materials
Materials are not specified.
Resources
ResourcesResources Language
S.P. Timoshenko, J.N. Goodier, Theory of Elasticity. McGraw-Hill, 3rd Edition, Singapore, 1984English
Course Assessment
Assesment MethodsPercentage (%)Assesment Methods Title
Final Exam50Final Exam
Midterm Exam50Midterm Exam
L+P: Lecture and Practice
PQ: Program Learning Outcomes
LO: Course Learning Outcomes